Human and mouse TGF beta 1 kit
Human and mouse TGF beta 1 kit standard
Alpha-SMA kit HTRF®
The Alpha-SMA kit is designed for the accurate quantitative measurement of Alpha-Smooth Muscle Actin produced by cells.
See more
-
No-wash
-
Low sample consumption
-
High sensitivity
Overview
After tissue injury, TGF-beta locally released by inflammatory cells activates resident fibroblasts or quiescent HSCs (hepatic stellate cells). This leads to their differentiation into myofibroblasts, whose role is to migrate into the damaged tissue and synthesize ECM (extracellular matrix) components to repair the wound. Myofibroblasts are characterized by de novo expression of alpha-SMA, which is incorporated into actin stress fibers and confers a high contractile activity to the cells. Chronic tissue injury leads to persistent de novo formation of myofibroblasts (alpha-SMA+), excessive contraction, and deposition of ECM, eventually leading to tissue fibrosis.
Benefits
- MYOFIBROBLAST DIFFERENTIATION STUDY
- FIBROTIC DISEASES STUDY
- STUDY OF TGF-BETA/SMAD3 PATHWAY
Assay principle
The alpha-SMA assay is based on a TR-FRET sandwich immunoassay format comprising two antibodies, one labelled with Eu3+-Cryptate (donor) and the other with d2 (acceptor). The antibodies specifically bind to Alpha-SMA, and the proximity of donor and acceptor leads to a fluorescent TR-FRET signal.
Assay Protocol
Two-plate assay protocol For added flexibility, the assay can be run under a two-plate assay protocol, where cells are plated, treated, and lysed in a culture plate. For detection, lysates are subsequently transferred into a 96- or 384-well low volume detection microplate, where the HTRF reagents are added. This protocol enables the cells' viability and confluence to be monitored. The detection reagents may be pre-mixed and added in a single dispensing step for direct detection. The assay can be run with frozen cell lysates or fresh cells in culture.
Specificity for Alpha-SMA isoform validated by siRNA experiments
The human hepatic stellate cell line LX-2* and the mouse fibroblast cell line NIH/3T3 were plated in culture-treated 96-well plates (10,000 cells/well) and incubated for 24h at 37°C - 5% CO2. The day after, the cells were transfected with an Alpha-SMA siRNA or with a negative control siRNA for 24h, and then treated or not with 2.5 ng/mL of TGF-ß1 for an additional 24 hours. After medium removal, the cells were lysed with supplemented lysis buffer #3 (50 µL for LX-2, or 200 µL for NIH/3T3) for 30 minutes at RT under gentle shaking. 16 µL of lysate were transferred into a low volume white microplate and 4 µL of the HTRF® Alpha-SMA detection antibodies were added. On both cell lines, transfection with the Alpha-SMA siRNA led to a huge decrease of the HTRF specific signal (~ 60 to 70%) compared to the cells transfected with the negative control siRNA, demonstrating that the HTRF® Alpha-SMA assay is specific for a-SMA isoform and does not cross-react with other actin isoforms.
* LX-2 cell line provided by EMD Millipore (product number #SCC064)
Alpha-SMA expression upon differentiation of HSCs into myofibroblasts
The human hepatic stellate cell line LX-2* was plated in a culture-treated 96-well plate (50,000 cells/well) in complete culture medium, and incubated at 37°C - 5% CO2. The day after, the cells were treated with increasing concentrations of TGF-beta1 for 48 hours. After medium removal, the cells were lysed with 50 µL of supplemented lysis buffer #3, and 16 µL of lysate were transferred into a low volume white microplate before the addition of 4 µL of the HTRF® Alpha-SMA detection antibodies. TGF-beta1 treatment induces a two-fold increase of Alpha-SMA expression level, highlighting the differentiation of HSCs into myofibroblasts.
* LX-2 cell line provided by EMD Millipore (product number #SCC064)
Primary HLFs differentiation into myofibroblasts in lung fibrosis
Primary human lung fibroblasts (HLFs) were plated in a culture-treated 96-well plate (20,000 cells/well) in complete culture medium and incubated overnight at 37°C - 5% CO2. Cells were then incubated for an additional 24 hours in serum-free medium before treatment with increasing concentrations of TGF-beta1 for 48 hours. After medium removal, cells were lysed with 50 µL of supplemented lysis buffer #3 for 30 minutes at RT under gentle shaking, and 16 µL of lysate were transferred into a low volume white plate before adding 4 µL of the HTRF® Alpha-SMA detection antibodies. The long-term treatment of cells with TGF-beta1 results in a four-fold increase in Alpha-SMA expression level, highlighting the differentiation of HLFs into myofibroblasts.
Alpha-SMA expression upon differentiation of fibroblasts into myofibroblasts
The mouse fibroblast cell line NIH/3T3 was plated in a culture-treated 96-well plate (6,250 and 12,500 cells/well) in complete culture medium, and incubated at 37°C - 5% CO2. The day after, the cells were treated with increasing concentrations of TGF-ß1 for 48 hours in serum-free and antibiotic-free culture medium supplemented with 0.2% BSA. After medium removal, the cells were lysed with 200 µL of supplemented lysis buffer #3 for 30 minutes at RT under gentle shaking, and 16 µL of lysate were transferred into a low volume white microplate before the addition of 4 µL of the HTRF® Alpha-SMA detection antibodies. The HTRF signal was recorded after an overnight incubation. TGF-beta1 long-term treatment results in a three-fold increase of Alpha-SMA expression level, which demonstrates the differentiation of fibroblasts into myofibroblasts.
HTRF Alpha-SMA assay compared to Western Blot
NIH/3T3 cells were seeded in a T175 flask, and incubated for 2 days at 37°C. After medium removal, the cells were lysed for 30 minutes at RT under gentle shaking. Soluble supernatants were collected after a 10-minute centrifugation. Serial dilutions of the cell lysate were performed in the supplemented lysis buffer, and 16 µL of each dilution were transferred into a low volume white microplate before the addition of 4 µL of the HTRF® Alpha-SMA detection reagents. Equal amounts of lysates were used for a side-by-side comparison with Western Blot. Using HTRF® Alpha-SMA detection reagents, just 200 cells were sufficient for minimal signal detection, while 800 cells were needed to detect a significant Western Blot signal. Thus the HTRF® Alpha-SMA assay is 4-fold more sensitive than the Western Blot.
TGF-beta signaling pathway
TGF-beta is a profibrotic cytokine that represents the main myofibroblast inducer. The SMAD-dependent TGF-beta signaling pathway involving the activation of the transcription factors SMAD2/3 leads to ACTA2 gene transcription and expression of alpha-SMA (a-Smooth Muscle Actin). This specific actin isoform is incorporated into actin stress fibers and gives the cells a strong contractile activity characteristic of differentiated myofibroblasts. TGF-beta also signals through SMAD-independent pathways by activating the TAK1-dependent kinases p38, JNK and NF-kappaB, as well as AKT and ERK kinases.
HTRF assays facilitate investigation of the TGFB/SMAD/a-SMA signaling axis in liver fibrosis
Benefits of using HTRF assays to characterize liver fibrosis - Technical Notes
Webinar: NASH - Fibrosis Research and Drug Discovery
Featuring a panel of experts - Videos
A collection of the most important NAFLD pathways
Useful overview of today’s NAFLD knowledge - Guides
HTRF Tools for the Successful Investigation of Tissue Fibrosis
Enhance your fibrosis studies - Application Notes
Product Insert a-SMA Kit / 62ASMAPEG-62ASMAPEH
62ASMAPEG-62ASMAPEH - Product Insert
All your HTRF assays in one document! - Catalog
A guide to Homogeneous Time Resolved Fluorescence
General principles of HTRF - Guides
HTRF assay for aSMA enables fast quantification of liver fibrosis
In collaboration with Physiogenex - Posters
How HTRF compares to Western Blot and ELISA
Get the brochure about technology comparison. - Brochures
Insight into fibrosis development and signaling pathways
A comprehensive overview of fibrosis development - Guides
Advance your research on Fibrosis
Kits and reagents for Fibrosis research - Flyers
Safety Data Sheet (DEU) a-SMA Kit / 62ASMAPEG
62ASMAPEG - Safety Data Sheet
Safety Data Sheet (ELL) a-SMA Kit / 62ASMAPEG
62ASMAPEG - Safety Data Sheet
Safety Data Sheet (FRA-FR) a-SMA Kit / 62ASMAPEG
62ASMAPEG - Safety Data Sheet
Safety Data Sheet (ITA) a-SMA Kit / 62ASMAPEG
62ASMAPEG - Safety Data Sheet
Safety Data Sheet (SPA) a-SMA Kit / 62ASMAPEG
62ASMAPEG - Safety Data Sheet
Safety Data Sheet (ENG-GB) a-SMA Kit / 62ASMAPEG
62ASMAPEG - Safety Data Sheet
Safety Data Sheet (ENG-US) a-SMA Kit / 62ASMAPEG
62ASMAPEG - Safety Data Sheet
Safety Data Sheet (DEU) a-SMA Kit / 62ASMAPEH
62ASMAPEH - Safety Data Sheet
Safety Data Sheet (ELL) a-SMA Kit / 62ASMAPEH
62ASMAPEH - Safety Data Sheet
Safety Data Sheet (FRA-FR) a-SMA Kit / 62ASMAPEH
62ASMAPEH - Safety Data Sheet
Safety Data Sheet (ITA) a-SMA Kit / 62ASMAPEH
62ASMAPEH - Safety Data Sheet
Safety Data Sheet (SPA) a-SMA Kit / 62ASMAPEH
62ASMAPEH - Safety Data Sheet
Safety Data Sheet (ENG-GB) a-SMA Kit / 62ASMAPEH
62ASMAPEH - Safety Data Sheet
Safety Data Sheet (ENG-US) a-SMA Kit / 62ASMAPEH
62ASMAPEH - Safety Data Sheet
Plate Reader Requirement
Choosing the right microplate reader ensures you’ll get an optimal readout. Discover our high performance reader, or verify if your lab equipment is going to be compatible with this detection technology.
Let's find your reader
You might be interested in